Self-validating data object locator for a media asset

ABSTRACT

Aspects of the disclosure relate to validation of a request for an asset based on information in the request. Validation of the request can be processed by a network node in a network repository that contains the asset. In one aspect, validation of the request can comprise determining if the request is legitimate based at least on processing at least a portion of the information in the request. In response to a legitimate request, the network node can process the request and, as a result, a data object associated with the asset can be supplied to a device originating the request. In the alternative, the network node can yield an exception.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.13/448,871, filed Apr. 17, 2012, which is herein incorporated byreference in its entirety.

BACKGROUND

In a web-based approach to delivery of media assets, content can beencapsulated into fragments, wherein a fragment is a data object thatcan be retained in a network repository (either distributed orlocalized) and can be accessed through hypertext transfer protocol(HTTP). Increasing number of such network transactions can becomeproblematic. Typically, the universal resource locator (URL) structurefor the fragments comprises information (e.g., parameters) related to atime code (TC) for a fragment and an associated quality level in bitsper seconds. Since the TC is not deterministic, a name space structurefor URLs of respective fragments generally is sparse, with valid namesbeing sparsely scattered in such name space. Accordingly, a properlyformatted uniform resource locator (URL) can be processed by a networkcentralized node (e.g., an origin server, or origin node, in a contentdistribution network (CDN)) even though such URL can convey an invalidname for a fragment, wherein the network central node can manage, atleast in part, the network repository. The network central node, in suchscenario, consumes operational resources for processing the requestcomprising the invalid URL and, typically, responds with an errormessage. Such processing can rapidly become inefficient for scaling as,for example, size of a name space of fragments increases.

SUMMARY

It is to be understood that this summary is not an extensive overview ofthe disclosure. This summary is exemplary and not restrictive, and it isintended to neither identify key or critical elements of the disclosurenor delineate the scope thereof. The sole purpose of this summary is toexplain and exemplify certain concepts of the disclosure as anintroduction to the following more detailed description.

Some embodiments of the disclosure relate to validation of a request foran asset based on information in the request. Validation of the requestcan be processed by a network node (e.g., edge cache node) in a networkrepository (e.g., a CDN) that contains the asset. In one aspect,validation of the request can comprise determining if the request islegitimate based at least on processing (e.g., hashing) at least aportion of the information in the request. In response to a legitimate(or valid) request, the network node can process the request, and a dataobject associated with the asset can be supplied to a device originatingthe request. In the alternative, the network node can yield anexception, such as transmission of an error notification to such device.

When compared to conventional technologies such as caching of accesserror codes or locally storing cookies, one or more embodiments of thedisclosure can afford various advantages related to validation ofrequest for fragments. For example, sparsity of the name space offragments associated with media assets can be accounted for byintegrating information into the queries, the information permittingvalidation of a query prior to consuming processing resources of anoriginating node. It should be appreciated that such integration can beaccomplished without substantive processing overhead, in view that anetwork edge node that processes such queries typically has availableprocessing resources since the node, being a cache node, can beprimarily bound by read/write operations. For another example,mitigation or avoidance of processing of non-legitimate queries forfragments can readily protect origin node(s) from denial-of-serviceattacks.

Additional aspects or advantages of the subject disclosure will be setforth in part in the description which follows, and in part will beapparent from the description, or may be learned by practice of thesubject disclosure. The advantages of the subject disclosure will berealized and attained by means of the elements and combinationsparticularly pointed out in the appended claims. It is to be understoodthat both the foregoing general description and the following detaileddescription are exemplary and explanatory only and are not restrictiveof the subject disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

The annexed drawings are an integral part of the subject disclosure andillustrate exemplary embodiments thereof. Together with the descriptionset forth herein and the claims appended hereto, the annexed drawingsserve to explain various principles, features, or aspects of the subjectdisclosure.

FIG. 1 illustrates an exemplary network environment in accordance withone or more aspects of the disclosure.

FIG. 2 illustrates an exemplary embodiment of a network in accordancewith one or more aspects of the disclosure.

FIG. 3 illustrates an exemplary embodiment of a network node inaccordance with one or more aspects of the disclosure.

FIG. 4 illustrates an exemplary embodiment of a device in accordancewith one or more aspects of the disclosure.

FIGS. 5-6 illustrate exemplary methods in accordance with one or moreaspects of the disclosure.

DETAILED DESCRIPTION

The various aspects described herein can be understood more readily byreference to the following detailed description of exemplary embodimentsof the subject disclosure and to the annexed drawings and their previousand following description.

Before the present systems, articles, apparatuses, and methods aredisclosed and described, it is to be understood that the subjectdisclosure is not limited to specific systems, articles, apparatuses,and methods for processing a request for an asset in a network. It isalso to be understood that the terminology used herein is for thepurpose of describing particular embodiments only and is not intended tobe limiting.

As used in the specification and the appended claims, the singular forms“a,” “an” and “the” include plural referents unless the context clearlydictates otherwise. Ranges may be expressed herein as from “about” oneparticular value, and/or to “about” another particular value. When sucha range is expressed, another embodiment includes from the oneparticular value and/or to the other particular value. Similarly, whenvalues are expressed as approximations, by use of the antecedent“about,” it will be understood that the particular value forms anotherembodiment. It will be further understood that the endpoints of each ofthe ranges are significant both in relation to the other endpoint, andindependently of the other endpoint.

As utilized in this specification and the annexed drawings, the terms“system,” “component,” “unit,” “interface,” “platform,” “node,”“function,” “engine” and the like are intended to include acomputer-related entity or an entity related to an operational apparatuswith one or more specific functionalities, wherein the computer-relatedentity or the entity related to the operational apparatus can be eitherhardware, a combination of hardware and software, software, or softwarein execution. Such entities also are referred to as “functionalelements.” As an example, a unit can be, but is not limited to being, aprocess running on a processor, a processor, an object (metadata object,data object, signaling object), an executable computer program, a threadof execution, a program, a memory (e.g., a hard-disc drive), and/or acomputer. As another example, a unit can be an apparatus with specificfunctionality provided by mechanical parts operated by electric orelectronic circuitry which is operated by a software application or afirmware application executed by a processor, wherein the processor canbe internal or external to the apparatus and can execute at least aportion of the software application or the firmware application. As yetanother example, a unit can be an apparatus that provides specificfunctionality through electronic functional elements without mechanicalparts, the electronic functional elements can include a processortherein to execute software or firmware that provides, at least in part,the functionality of the electronic functional elements. The foregoingexamples and related illustrations are but a few examples and are notintended to be limiting. In addition, while such illustrations arepresented for a unit, the foregoing examples also apply to a node, afunction, a controller, a component, a system, a platform, and the like.It is noted that in certain embodiments, or in connection with certainaspects or features such embodiments, the terms “unit,” “component,”“system,” “interface,” “platform” “node,” “function,” “engine” can beutilized interchangeably.

Throughout the description and claims of this specification, the words“comprise” and “having” and their variations, such as “comprising” and“comprises,” “having” and “has,” mean “including but not limited to,”and are not intended to exclude, for example, other units, nodes,components, functions, interfaces, actions, steps, or the like.“Exemplary” means “an example of” and is not intended to convey anindication of a preferred or ideal embodiment. “Such as” is not used ina restrictive sense, but for explanatory purposes.

Reference will now be made in detail to the various embodiments andrelated aspects of the subject disclosure, examples of which areillustrated in the accompanying drawings and their previous andfollowing description. Wherever possible, the same reference numbers areused throughout the drawings to refer to the same or like parts.

One aspect of the disclosure identifies and addresses the issue ofsparsity of the name space structure of data objects associated with amedia asset. Such sparsity refers to presence of scattered valid valuesfor names of such data objects even though the names having a welldefined format. As described in greater detail below, the disclosurerelates to processing queries for data objects, such as fragments,associated with a media asset. Certain functional elements of thedisclosure can be implemented (e.g., performed) by software, hardware,or a combination of software and hardware. Functional elements of thevarious embodiment(s) described in the present specification andillustrated in the annexed drawings can be employed in operationalenvironments (access network, telecommunication network, signalingnetwork, etc.) that can include, for example, digital equipment, analogequipment, or both, wired or wireless equipment, etc.

Referring to the drawings, FIG. 1 illustrates a high-level block diagramof an exemplary network environment 100 in accordance with one or moreaspects of the disclosure. In the exemplary network environment 100, anetwork repository can be queried for a data object associated with amedia asset in accordance with one or more aspects of the disclosure. Asillustrated, the exemplary network environment 100 comprises a device110 functionally coupled (e.g., communicatively coupled via wired linksor wireless links, or a combination thereof) to an access/delivery (A/D)network 120 which can include wireless networks, wireline networks, andany combination thereof. A data and signaling pipe 114 comprising anupstream link, or uplink (UL), and a downstream link, or downlink (DL),enables functional coupling among the device 110 and the network 120.The data and signaling pipe 114 can comprise a wireless link or wirelinelink, or a combination thereof. Device 110 can be embodied in or cancomprise end-user equipment, such as a user device (mobile or otherwise)or most any customer premises equipment. Accordingly, device 110 can bean electronic device that is part of a network (e.g., atelecommunication network, a home network, a utilities network, orcombinations thereof) and has various levels of computationalcapability. For example, the device 110 can be at least one of aterminal display device, a set top box (STB), an internet protocol(IP)-enabled television, a personal computer, a portable computer, awearable computer, and so forth.

In one aspect, the device 110 can transmit an object request 116 toquery a network repository (e.g., a content distribution network (CDN))for a fragment (or data object) associated with a media asset intendedto be received and/or consumed at the device 110. To transmit the objectrequest 116 to the network repository, the device 110 can exploit thenetwork 120, to which the device 110 can communicate in accordance withvarious packet-switched (PS) communication protocols supported by suchnetwork. For instance, the various packet-switched communicationprotocols can include one or more of an Ethernet protocol format; aninternet protocol (IP) format, such as IPv4 and IPv6, or the like; auser datagram protocol (UDP) format; HTTP; simple object access protocol(SOAP); or simple network management protocol (SNMP). Accordingly, inone aspect, device 110 can compose the object request 116 according toat least one of such protocols. When the object request 116 is composedaccording to HTTP, the object request 116 can adopt, for example, thefollowing form:“http://streamer02.delivery-service-name.cdn2.comcast.net/key-id(138)/espn/timecode(42)/qualitylevel(300000)/hash(4ed345)”.Such object request 116 comprises at least two portions, e.g.,“key-id(138) and “hash(4ed345)” indicative, respectively, of a keyidentifier (key ID) and a hash value. A first portion of the at leasttwo portions can be referred to as a first identifier (e.g.,“key-id(138)”) indicative of a first value, and a second portion of theat least two portions can be referred to as second identifier (e.g.,“hash(4ed345)”) indicative of a second value. More generally, inscenarios in which the object request 116 is composed according to aformat other than HTTP, the object request 116 can comprise a firstvalue suitably formatted and indicative of a key ID, and a second valuesuitably formatted and indicative of a reference hash value. Asdescribed herein, the key ID and the reference hash value can render theobject request 116 a self-validating object resource locator in responseto processing by the network repository.

The network 120 can include wireless networks, wireline networks, andany combination thereof, which can transmit the object request 116 tothe network repository (e.g., CDN 140). In one aspect, the network 120can include one or more of wide area networks (WANs), one or more localarea networks (LANs), signaling networks (e.g., SS #7), etc.), and soforth. Such networks can operate in accordance with most anycommunication protocol for wireline communication or wirelesscommunication. In certain embodiments, network 120 can have severalfunctional elements that can provide a backbone network, such as ahigh-capacity packet-switched network. In other embodiments, network 120can have internal structure, with several functional elements that canprovide at least two main operational blocks: a backbone network (e.g.,a high-capacity packet-switched network) and a regional access network(RAN). The internal structure also can include functional elements thatprovide more spatially localized networks, such as local area networks,home area networks, or the like. Both the backbone network and theregional access network (RAN) can be WANs, for example, with thebackbone network having a larger geographical scope than the RAN.

In one embodiment (e.g., exemplary embodiment 200 shown in FIG. 2 ), thenetwork 120 can comprise a core network platform 230 functionallycoupled with the CDN 140. The core network platform 230 can includevarious network nodes which can be distinguished according to theirfunctionality. As illustrated, the various network nodes can compriseone or more servers 232, and one or more nodes 238 (e.g., gatewaynode(s)). The one or more servers 232 can comprise, for example,adaptation layer units, application server(s), management server(s),proxy server(s), and the like. Functionality and architecture of the oneor more servers 232 and the one or more nodes 238 generally is specific,yet not exclusive, to the embodiment of the core network platform 120.For instance, in an exemplary embodiment in which the core networkplatform 230 embodies or comprises an IMS network, server(s) 122 cancomprise application server(s), and specific function control nodes(e.g., Call Session Control Functions (CSCFs), such as serving CSCF(S-CSCF) and interrogating CSCF (I-CSCF)) and proxy servers; and node(s)238 can comprise one or more gateway nodes having a breakout gatewaycontrol function (BGCF), a media gateway (MGW) and a signaling gateway(SGW), and media gateway control function (MGCF).

Network nodes in core network platform 230 can be functionally coupledthrough a bus 236. As illustrated, the bus 126 can enable exchange ofinformation (e.g., data or signaling, or both) among server(s) 232 andnode(s) 238 (e.g., gateway node(s), also referred to as gateway(s)). Incertain embodiments, bus 236 can include a plurality of reference links(Cx, Cr, Dh, Dx, Gm, Ma, Mg, etc.), and related components, and busarchitectures such as address buses, system buses, and the like.

The core network platform 230 can permit implementation of variousnetwork management operations (access authorization and accounting,provisioning, billing, etc.); content integrity monitoring; or networkfunctionality comprising programming monitoring, advertisementmonitoring, or both. In addition or in the alternative, the core networkplatform 230 can include an application layer having at least one serverof the one or more servers 232. The at least one server in theapplication layer can provide media content, such as media assets, whichcan be either linear-programming assets or non-linear assets (e.g.,media-on-demand). In one aspect of web-based transmission of the mediacontent, the at least one server can comprise a content server (notshown) that can encapsulate, or partition, the media content intofragments, or data objects. In one aspect, the content server (notshown) can format the fragments, or data objects, in accordance with anyformat (e.g., joint photographic experts group (JPEG) file interchangeformat (JFIF)) suitable for packet-switched transmission of mediacontent. Encapsulation into fragments, also referred to asfragmentation, of a media asset can comprise compression of such asset.In one implementation, compression can be accomplished according to theJPEG compression method.

As illustrated in exemplary embodiment 200, the A/D network 120 cancomprise a distribution platform 220 which can be functionality coupledto the core network platform 230 via a data and signaling pipe 235.Similarly to other data and signaling pipes disclosed herein, the dataand signaling pipe 235 can comprise one or more of: a reference link,and related components; a conventional bus architectures such as addressbuses, system buses; wired links, such as fiber optic links, coaxiallinks, hybrid fiber-coaxial links, and various connectors (e.g., anEthernet connector, an F connector, an RS-232 connector, or the like);wireless links (either terrestrial links or deep-space links); and soforth.

The distribution platform 220 can comprise one or more signal processingcomponents (not shown) that can receive and operate on an informationstream, such as a data stream, a signaling stream, or a combinationthereof. Such component(s) can perform one or more operations on theinformation stream, such as encoding, modulation, multiplexing,up-conversion, combination, and the like. In one embodiment, at leastone of such signal processing component(s) can embody a terminationsystem (e.g., a cable modem termination system (CMTS)). In otherembodiments, each edge originating node of the group of one or more edgeoriginating nodes 224 can embody a network router (e.g., broadbandremote access server (BRAS)) or a network switch (e.g., a DSLAM) fortransmission of information streams based on a packet-switched (PS)communication protocol (e.g., internet protocol). While illustrated as asingle block, in one or more embodiment(s), distribution platform 220can be distributed, having a centralized deployment site (or plant) anda plurality of hub sites (also referred to as sites). In suchembodiment(s), each one of the hub sites can comprise an edgeoriginating node of the group of one or more edge originating nodes 224.

The distribution platform 220 can receive data (data flows, audiosignals, video signals, any combinations thereof, etc.) and signaling(control instructions, clock signals, etc.) from a unit that is part,for example, of core network platform 230 or that is functionallycoupled thereto. Such unit can relay the data from the CDN 140. Inaddition or in the alternative, the unit can originate the data andsignaling, and convey such information to the distribution platform 220.In one scenario, the unit can be a server (e.g., one of server(s) 232)that can supply a combination of audio signal and video signal, such asan audiovisual signal comprising a video asset. The server can be, forexample, the foregoing content server (not shown) which can generatemedia content for pay-per-view programming or video-on-demand assets, anapplication server (e.g., an email server), a data server, a telephonyserver, a backbone network router, or the like. In such scenario, basedon the formatting of the audiovisual signal, one or more signalprocessing components (not shown) in the distribution platform 220 canprocess (encode, encrypt, modulate, multiplex, up-convert, combine) theaudiovisual signal and supply a resulting audiovisual signal to an edgeoriginating node of the group of one or more edge originating nodes 224.An edge originating node can transmit a plurality of data streams,conveying at least a portion of the audiovisual signal. It should beappreciated that in certain embodiments, the edge originating node canprocess the audiovisual signal without reliance on such one or moresignal processing components. In another scenario, a source node (e.g.,a satellite transceiver coupled to an asset source) can be coupled tothe distribution platform 220 and can generate an audiovisual signal,which can be processed by one or more processing components and suppliedto an edge originating node of the one or more edge originating nodes224. Such edge originating node can transmit a plurality of data streamsconveying at least a portion of the audiovisual signal.

As illustrated, the exemplary embodiment 200 also can comprise afragmentor unit 240 that can encapsulate, or partition, the mediacontent into fragments, or data objects. In one aspect, the fragmentorunit 240 can format the fragments, or data objects, in accordance withany format (e.g., JFIF) suitable for packet-switched transmission ofmedia content. Encapsulation into fragments, also referred to asfragmentation, of a media asset can comprise compression of such asset.In one implementation, compression can be accomplished according to theJPEG compression method. While in the illustrated embodiment thefragmentor unit 240 is external to the core network platform 230—as itmay be the scenario when content is encapsulated by an entity other thana service provider that operates the core network platform 230—in otherembodiments the fragmentor unit 240 can be part of the core networkplatform 230 (e.g., a server of the server(s) 232 can comprise or embodythe fragmentor unit 240.

In the illustrated embodiment, the A/D network 120 also can comprise atransport network 210 can be a WAN that can be embodied in a wirelessnetwork, a wireline network, or a combination thereof, and supplies dataservice(s), such as television programming, video on demand, internetservice, packet-switched telephony, to a user location which can bestationary (e.g., a location of a dwelling (residential or enterprise))or mobile (e.g., a location of a mobile device). Transport network 210can be embodied in an optic fiber network, a coaxial cable network, oran HFC network, an optic fiber network, a coaxial network, a wirelessnetwork, and the like. In an embodiment in which the transport network210 is an HFC network, data pipe and signaling 205 can comprise severaloptic fiber links and associated optical functional elements, such asdownstream lasers, light amplifiers, last-mile fiber aggregator node,and the like. In addition, in such embodiment, the transport network 210can comprise various RF amplifiers and coaxial taps to respectivedwellings (residential, multi-unit, enterprise, etc.) wherein the device110 can consume a data service (e.g., internet service) provided throughthe various networks in the exemplary network environment 100. In oneaspect, the device 110 can be functionally coupled to a cable modem orother device (e.g., a network interface device (NID)) that serves as thenetwork gateway to the dwelling network from the transport network 210.As another illustration, in an embodiment in which the transport network210 is a wired broadband packet-switched network, data and signalingpipes 215 and 205 can comprise Ethernet links, T-1 carriers, and/orfiber optic links, and can include network routers such as BRASs andnetwork switching, such as DSLAMs. The network switches can befunctionally coupled to home gateways (e.g., DSL modems) in a dwellingin which the device 110 can consume or can enable data services (e.g.,internet service) provided through the various networks in the exemplarynetwork environment 100.

As described herein, the network 120, via a functional element thereof,can be functionally coupled to the network repository for which theobject request 116 is intended to. In the exemplary network environment100, a CDN 140 embodies the network repository. The CDN 140 can comprisea set of one or more edge cache nodes 130 and at least one intermediatelayer having one or more cache nodes. In the illustrated embodiment, theCDN 140 comprises two intermediate layers: a first layer comprising aset one or more cache nodes 132, and a second layer comprising a set ofone or more cache nodes 134. In one aspect, an intermediate layer canincrease redundancy and thus increase resilience of the CDN 140 tofailure and accessibility to information retained therein. The set ofone or more edge cache nodes 130 can be functionally coupled, via a dataand signaling pipe 135, to at least one (e.g., one, two, more than two,all) of the cache nodes of the set of one or more cache nodes 132. Inscenarios in which the set of one or more cache nodes 132 comprises atleast two nodes, the at least two nodes can be mutually functionallycoupled. At least one cache node of the set of one or more cache nodes132 can be functionally coupled, via a data and signaling pipe 137, toat least one node of a set of one or more cache nodes 134. In scenariosin which the set of one or more cache nodes 134 comprises at least twonodes, at least such nodes can be mutually functionally coupled. Atleast one node of the set of one or more cache nodes 134 can befunctionally coupled, via a data and signaling pipe 139, to an originnode 150 (which also can be referred to as a central node 150).

In one aspect of the exemplary network environment 100, functionalconnectivity among the edge cache node(s) 130, the cache node(s) 132,and the cache node(s) 134 permits indirect functional coupling (wired,wireless, or any combination thereof) among at least one of the edgecache node(s) 130 and the origin node 150. Such coupling can permittransmission of information (such as the object request 116) from aspecific one of the edge cache node(s) 130 to the origin node 150.Similarly, such indirect coupling can permit transmission of information(e.g., data or metadata) from the origin node 150 to the specific nodeof the edge cache node(s) 130. In additional or alternative embodimentsof exemplary network environment 100, the intermediate layers of cachenodes (e.g., cache node(s) 132 and cache node(s) 134) can be absent,permitting direct functional coupling, and related information exchange,among at least one edge cache node of the edge cache node(s) 130 and theorigin node 150.

In one aspect, the CDN 140 can have a larger geographical scope than thenetwork 120. In one embodiment, communication through the link 135 canbe effected in accordance with one or more packet-switched protocols,such as TCP/IP, UDP, Ethernet protocol, or the like. Similarly to otherdata and signaling pipes described herein, the data and signaling pipe135 can comprise one or more of: a reference link, and relatedcomponents; a conventional bus architectures such as address buses,system buses; wired links, such as fiber optic lines, coaxial lines,hybrid fiber-coaxial links, Ethernet lines, T-carrier lines,twisted-pair line, or the like, and various connectors (e.g., anEthernet connector, an F connector, an RS-232 connector, or the like);wireless links, including terrestrial wireless links, satellite-basedwireless links, or a combination thereof; and so forth.

As illustrated, the network 120 is functionally coupled to the CDN 140via a data and signaling pipe 125 having an UL and a DL. The data andsignaling pipe 125 can comprise one or more of: a reference link, andrelated components; a conventional bus architectures such as addressbuses, system buses; wired links, such as fiber optic lines, coaxiallines, hybrid fiber-coaxial links, Ethernet lines, T-carrier lines,twisted-pair line, or the like, and various connectors (e.g., anEthernet connector, an F connector, an RS-232 connector, or the like);wireless links, including terrestrial wireless links, satellite-basedwireless links, or a combination thereof; and so forth.

In one aspect, the network 120 can be functionally coupled tocommunicate with the CDN 140 via an edge cache node of the set of one ormore edge cache nodes 130. A functional element, (e.g., a server or agateway node) of the network 120 can enable such coupling. Suchfunctional element can deliver the object request 116 to such edge cachenode, wherein the edge cache node can be configured to receiveinformation indicative of a requested data object, and can process theobject request 116 as part of a response to the query conveyed by suchrequest. Such information can be formatted according to a specificcommunication protocol, such as a web-based communication protocol whichcan comprise at least one of HTTP, SOAP, or SNMP.

To process the object request 116, which, for example, can comprise afirst identifier (e.g., a key ID) indicative of a first value (e.g. areceived key value) and a second identifier indicative of the secondvalue (e.g., a reference hash value), the edge cache node of the set ofone or more edge cache nodes 130 can determine if the request islegitimate based at least on the second value. In certain embodiments,the first identifier and the second identifier can be embodied or cancomprise in respective portions of a uniform resource locator (URL)embodying the object request 116. It should be appreciated that the edgecache node can ascertain the validity of the object request 116algorithmically, as opposed to empirically, for example. Therefore, inview of the incorporation of data indicative of the key ID and thesecond value (e.g., a hash value) into the object request 116, suchrequest can serve as a self-validating resource locator. It should beappreciated that in scenarios in which the second value is a hash value,the hash value can be generated via a signed hashing (or signed hashmethod) that can contain the key value that is included or embodied inthe first value contained in the request 116. Accordingly, the secondvalue can be a signed hash value signed by the key value included orembodied in the first value. To determine if the request is valid basedat least on the second value, the edge cache node can, initially,validate the first value by ascertaining that the received key valueassociated with the first value is present in a mapping that relates atleast one key identifier to at least one key value. The mapping can be,in one aspect, a one-to-one mapping, a one-to-many mapping, or amany-to-many mapping. In one embodiment (e.g., edge cache node 310 inFIG. 3 ), the mapping (e.g., one of the ID-value mapping(s) 321) can becontained in a memory (e.g., data storage 320) of the edge cache node.In one implementation, the mapping can be provisioned to the edge cachenode (e.g., edge cache node 310) in a similar manner to provisioning ofa delivery service (DS) name. In one aspect, each of the edge cachenodes of the one or more edge cache nodes 130 can be provisioned withkey information, such as key values, ID-value mappings, acceptableformats for key IDs, and the like, in a manner similar to that ofprovisioning DS(s) to each of such nodes. The key information can beencrypted prior to storage in the edge cache node.

In response to the first value being valid, the edge cache node candetermine a third value, such as a checksum value, by evaluating afunction (e.g., a hash function) of data indicative of at least aportion of the information (e.g., the URL name) indicative of therequested data object. In one aspect, the checksum value can include akey value that renders the checksum value a signed checksum value,wherein the key value can be the valid first value. To determine thethird value, the edge cache node can determine the checksum value byperforming a hash, e.g., implementing a specific hash algorithm (orhashing), of at least a portion of the information. The hashing can be asigned hashing which contains a key value in the specific hash algorithmassociated with the signed hashing. In contrast to non-signedconventional hashing, the signed hashing can yield a signed checksumvalue, or signed hash value, being signed according to the key value.For a third value that coincides with the second value conveyed by theobject request 116, such request is deemed valid. In an examplescenario, for an object request 116 embodied in“http://streamer02.delivery-service-name.cdn2.comcast.net/key-id(138)/espn/timecode(42)/qualitylevel(300000)/hash(4ed345)”,at least the portion of the information can be embodied in“key-id(138)/espn/timecode(42)/qualitylevel(300000)/hash(4ed345)”. Inaddition, in such example, the key value is “138”, whereas the referencehash value is “4ed345”. Upon or after validation of the “138” value, theedge cache node can determine the checksum value associated with suchvalue and the portion of the foregoing URL by computing an MD5message-digest algorithm, for example. If outcome of such computationdoes not yield “4ed345”, the exemplary object request 116 is invalid andthe edge cache node can transmit an error notification such as an HTTP404 status code.

In response to the object request 116 being valid, or legitimate, theedge cache node can proceed with processing the object request 116. Aspart of such processing, in one aspect, the edge cache node can transmitthe object request 116 to the origin node 150. The edge cache node canreceive, from the origin node 150, the data object (e.g., a mediacontent fragment) requested in the object request 116 in response tosuch request. In response to the object request 116 being invalid, ornon-legitimate, the edge cache node can transmit an error notification(e.g., an HTTP 404 status code) to the device 110, via the network 120.

For the exemplary embodiment 200 of the network 120, in response togeneration of a fragment, or a data object, the described content server(not shown) and the fragmentor unit 240 can issue a key value and cancompute a hash value associated with the key value and at least aportion of an object resource locator (e.g., a URL) assigned to thefragment, or the data object. Such hash value can be the reference hashvalue for the key and at least the portion of the object resourcelocator. In one aspect, for linear-programming assets, the fragmentorunit 240 can compute hash values for respective TC+1 and TC+2 and eachquality level associated therewith. The fragmentor unit 240 can retainsuch values in a universally unique identifier (UUID) box, or field, ofa specific length in bytes in a fragment header. The term box generallyis employed in reference to Moving Pictures Experts Groups(MPEG)-formatted fragments. The device 110 can exploit such informationto determine a suitable hash value to be employed for next-timecode andqualitylevel values for insertion into an object resource locatorassociated with an object request. The fragmentor unit 240 also canutilize an encryption key that can be available to one or morecomponents of the distribution platform 220, or a new UUID box, orfield, of a specific length in bytes can be inserted into a fragment(e.g., a movie fragment (or MOOF, as referred to in MPEG-4 formattedcontent) which details a key ID to be incorporated into the objectresource locator.

In another aspect, for non-linear assets, such as video-on-demand assetsor time-shifted assets, the fragmentor unit 240 can add a new field toeach chunk time reference which can include the hash value to beemployed for a current timecode and each possible quality level. The keyID that can be utilized in an object resource locator (e.g., a URL) canbe provided to the device 110 as part of a manifest metadata.

FIG. 3 is a block diagram of an exemplary embodiment of an edge cachenode 310 in accordance with one or more aspects of the disclosure. Edgecache node 310 is an apparatus that can embody or can comprise a node ofthe set of one or more network edge nodes 130. In certain embodiments,edge cache node 310 can embody or can comprise a node in the set of oneor more cache nodes 132 or in the set of one or more cache nodes 134. Inthe illustrated embodiment, the network node 310 comprises a group ofone or more I/O interfaces 304, a group of one or more processors 308, amemory 316, and a bus 312 that functionally couples (e.g.,communicatively couples) various functional elements of the edge cachednode 310 including the group of one or more processors 308 to the memory316. In scenarios in which operation of network node 310 can be criticalto network performance, such as in guaranteed service quality (e.g.,guaranteed bit rate) scenarios, the group of one or more processors 308can comprise a plurality of processors that can exploit concurrentcomputing.

Functionality of edge cache node 310 can be configured by a group ofcomputer-executable instructions (e.g., programming code instructions orprogramming modules) that can be executed by a processor of the one ormore processors 308. Generally, programming modules can comprisecomputer code, routines, objects, components, data structures (e.g.,metadata objects, data object, control objects), and so forth, that canbe configured (e.g., coded or programmed) to perform a particular actionor implement particular abstract data types in response to execution bythe processor. For example, a first group of computer-executableinstructions can configure logic that, in response to execution by theprocessor, enables the edge cache node 310 to operate as a server (aprovisioning server, an AAA server, a proxy server, a communicationmanagement server, an application server, etc.), a gateway node (asession border controller (SBC), or a media gateway control function((MGCF), etc.).

Data and computer-accessible instructions, e.g., computer-readableinstructions and computer-executable instructions, associated withspecific functionality of the edge cache node 310 can be retained inmemory 316. Such data and instructions can permit implementation, atleast in part, of the validation of a request for an asset (e.g., a dataobject) based on information in the request in accordance with aspectsdescribed herein. In one aspect, the computer-accessible instructionscan embody any number of programming code instructions or programmodules that permit specific functionality. In the subject specificationand annexed drawings, memory elements are illustrated as discreteblocks, however, such memory elements and related computer-accessibleinstructions, e.g., computer-readable and computer-executableinstructions, and data can reside at various times in different storageelements (registers, files, memory addresses, etc.; not shown) in memory316.

Data storage 320 can comprise a variety of data, metadata, or bothassociated with validation of a request for an asset (e.g., a dataobject) based on information in the request in accordance with aspectsdescribed herein. Memory 316 also can comprise one or morecomputer-executable instructions for implementation of specificfunctionality of the edge cache node 310 in connection with thevalidation of a request for an asset (e.g., a data object) based oninformation in the request described herein. Such computer-executableinstructions can be retained as a memory element labeled requestprocessing instruction(s) 318. In one aspect, as described herein, therequest processing instruction(s) 318 can be stored as an implementation(e.g., a compiled instance) of one or more computer-executableinstructions that implement and thus provide at least the functionalityof the methods described herein. The request processing instruction(s)318 also can be transmitted across some form of computer readable media.It should be appreciate that different request processing instructionscan render physically alike edge cache nodes into functionally differentcomponents, with functional differences dictated by logic (e.g.,computer-executable instructions and data) specific to each one of suchnetwork nodes and defined by the request processing instructions.

Memory 316 can be embodied in a variety of computer-readable media.Exemplary computer-readable media can be any available media that isaccessible by a processor in a computing device, such as one processorof the group of one or more processors 308, and comprises, for example,both volatile and non-volatile media, removable and non-removable media.As an example, computer-readable media can comprise “computer storagemedia,” or “computer-readable storage media,” and “communicationsmedia.” Such storage media can be non-transitory storage media.“Computer storage media” comprise volatile and non-volatile, removableand non-removable media implemented in any methods or technology forstorage of information such as computer readable instructions, datastructures, program modules, or other data. Exemplary computer storagemedia comprises, but is not limited to, RAM, ROM, EEPROM, flash memoryor other memory technology, CD-ROM, digital versatile disks (DVD) orother optical storage, magnetic cassettes, magnetic tape, magnetic diskstorage or other magnetic storage devices, or any other medium which canbe utilized to store the desired information and which can be accessedby a computer or a processor therein or functionally coupled thereto.

Memory 316 can comprise computer-readable non-transitory storage mediain the form of volatile memory, such as random access memory (RAM),electrically erasable programmable read-only memory (EEPROM), and thelike, or non-volatile memory such as read only memory (ROM). In oneaspect, memory 316 can be partitioned into a system memory (not shown)that can contain data and/or programming modules that enable essentialoperation and control of the edge cache node 310. Such program modulescan be implemented (e.g., compiled and stored) in memory element 322,referred to as operating system (OS) instruction(s) 322, whereas suchdata can be system data that is retained in memory element 324, referredto as system data storage 324. The OS instruction(s) 322 and system datastorage 324 can be immediately accessible to and/or are presentlyoperated on by at least one processor of the group of one or moreprocessors 308. The OS instruction(s) 322 can embody an operating systemfor the edge cache node 310. Specific implementation of such OS candepend in part on architectural complexity of the edge cache unit 310.Higher complexity affords higher-level OSs. Example operating systemscan include Unix, Linux, iOS, Windows operating system, andsubstantially any operating system for a computing device.

Memory 316 can comprise other removable/non-removable,volatile/non-volatile computer-readable non-transitory storage media. Asan example, memory 316 can include a mass storage unit (not shown) whichcan provide non-volatile storage of computer code, computer readableinstructions, data structures, program modules, and other data for theedge cache node 310. A specific implementation of such mass storage unit(not shown) can depend on desired form factor of and space available fordeployment of the edge cache node 310. For suitable form factors andsizes of the monitoring device, the mass storage unit (not shown) can bea hard disk, a removable magnetic disk, a removable optical disk,magnetic cassettes or other magnetic storage devices, flash memorycards, CD-ROM, digital versatile disks (DVD) or other optical storage,random access memories (RAM), read only memories (ROM), electricallyerasable programmable read-only memory (EEPROM), or the like.

Features of validation of a request for an asset (e.g., a data object)based on information in the request in accordance with aspects describedherein can be performed, at least in part, in response to execution ofsoftware components (e.g., one or more implementations of requestprocessing instruction(s) 318) by a processor. In particular, yet notexclusively, to provide the specific functionality of edge cache node310, a processor of the group of one or more processors 308 in edgecache node 310 can execute at least a portion of request processinginstruction(s) 318, consuming data from or injecting data into datastorage 320 in accordance with aspects of the disclosure, wherein suchdata can be retained in a memory element (e.g., register, file,database, memory page, or the like) labeled cached data 323.

In general, a processor of the group of one or more processors 308 canrefer to any computing processing unit or processing device comprising asingle-core processor, a single-core processor with software multithreadexecution capability, multi-core processors, multi-core processors withsoftware multithread execution capability, multi-core processors withhardware multithread technology, parallel platforms, and parallelplatforms with distributed shared memory (e.g., a cache). In addition orin the alternative, a processor of the group of one or more processors308 can refer to an integrated circuit with dedicated functionality,such as an application specific integrated circuit (ASIC), a digitalsignal processor (DSP), a field programmable gate array (FPGA), acomplex programmable logic device (CPLD), a discrete gate or transistorlogic, discrete hardware components, or any combination thereof designedto perform the functions described herein. In one aspect, processorsreferred to herein can exploit nano-scale architectures such as,molecular and quantum-dot based transistors, switches and gates, inorder to optimize space usage (e.g., improve form factor) or enhanceperformance of the computing devices that can implement the variousaspects of the disclosure. In another aspect, the one or more processors308 can be implemented as a combination of computing processing units.

The one or more input/output (I/O) interfaces 304 can functionallycouple (e.g., communicatively couple) edge cache node 310 to anotherfunctional element (component, unit, server, gateway node, repository,etc.) of network 120, for example. Functionality of the edge cache node310 that is associated with data I/O or signaling I/O can beaccomplished in response to execution, by a processor of the group ofone or more processors 308, of at least one I/O interface retained inmemory element 328. Such memory element being represented by the blockI/O interface(s) 328. In some embodiments, the at least one I/Ointerface embodies an API that permit exchange of data or signaling, orboth, via an I/O interface of I/O interface(s) 304. In certainembodiments, the one or more I/O interfaces 304 can include at least oneport that can permit connection of the edge cache node 310 to otherfunctional element of the exemplary network environment 100. In one ormore scenarios, the at least one port can comprise network adaptor(s)such as those present in reference links, and other network nodes. Inother scenarios, the at least one port can include one or more of aparallel port (e.g., GPIB, IEEE-1284), a serial port (e.g., RS-232,universal serial bus (USB), FireWire or IEEE-1394), an Ethernet port, aV.35 port, or the like. The at least one I/O interface of the one ormore I/O interfaces 304 can enable delivery of output (e.g., outputdata, output signaling) to such functional element. Such output canrepresent an outcome or a specific action of one or more actionsdescribed herein, such as in the method of FIG. 5 .

Bus 312 represents one or more of several types of bus structures,including a memory bus or memory controller, a peripheral bus, anaccelerated graphics port, and a processor or local bus using any of avariety of bus architectures. As an example, such architectures cancomprise an Industry Standard Architecture (ISA) bus, a Micro ChannelArchitecture (MCA) bus, an Enhanced ISA (EISA) bus, a Video ElectronicsStandards Association (VESA) local bus, an Accelerated Graphics Port(AGP) bus, and a Peripheral Component Interconnects (PCI), a PCI-Expressbus, a Personal Computer Memory Card Industry Association (PCMCIA),Universal Serial Bus (USB), and the like.

FIG. 4 is a block diagram of an exemplary embodiment 400 of the device110 in accordance with one or more aspects of the disclosure. Asdescribed herein, the device 110, in the exemplary embodiment 400 cancommunicate a self-validating request for a data object associated witha media asset. In the illustrated embodiment, the device 110 cancomprise a memory 416 having computer-accessible instructions, e.g.,computer-readable computer-executable instructions, encoded thereon.Such instructions can be retained as request composition instruction(s)in a memory element 418. In addition, the device 110 can comprise aprocessor (e.g., one of processor(s) 408) functionally coupled to thememory 416 and configured, by the computer-executable instructions. Theprocessor also can be configured to generate a request for a dataobject, the request comprising an identifier indicative of a firstvalue, and a second value, and to transmit the request for the dataobject to a first network node, wherein the first network node isconfigured to validate the request and, in response to the request beingvalid, transmit the request to a second network node. In certainembodiments, the first network node can be one of network edge cachenode(s) 130. In one aspect, the first value can be a key identifier of akey value in a mapping relating at least one key identifier to at leastone key value. The second value is a predetermined hash value related tothe key value. In one aspect, as described herein, the predeterminedhash value can comprise the key value and can be referred to as a signedhash value.

To generate the request for the data object, the processor can beconfigured to format the request according to a specific communicationprotocol, the data object being a media content fragment. In one aspect,the specific communication protocol can be a web-based communicationprotocol comprising at least one of hypertext transfer protocol (HTTP),simple object access protocol (SOAP), or simple network managementprotocol (SNMP).

As illustrated, in the exemplary embodiment 400, the device 110comprises a group of one or more I/O interfaces 404, a group of one ormore processors 408, a memory 416, and a bus 412 that functionallycouples various functional elements of the device 110 including thegroup of one or more processors 408 to the memory 416. In scenarios inwhich operation of the device 110 can be critical to networkperformance, such as in guaranteed service quality scenarios, the groupof one or more processors 408 can comprise a plurality of processorsthat can exploit concurrent computing.

Functionality of the device 110 can be configured by a group ofcomputer-executable instructions (e.g., programming code instructions orprogramming modules) that can be executed by a processor of the one ormore processors 408. Generally, programming modules can comprisecomputer code, routines, objects, components, data structures (e.g.,metadata objects, data object, control objects), and so forth, that canbe configured (e.g., coded or programmed) to perform a particular actionor implement particular abstract data types in response to execution bythe processor.

Data and computer-accessible instructions, e.g., computer-readableinstructions and computer-executable instructions, associated withspecific functionality of the device 110 can be retained in memory 416.Such data and instructions can permit implementation, at least in part,of the validation of a request for an asset (e.g., a data object) basedon information in the request in accordance with aspects describedherein. In one aspect, the computer-accessible instructions can embodyany number of programming code instructions or program modules thatpermit specific functionality. In the subject specification and annexeddrawings, memory elements are illustrated as discrete blocks, however,such memory elements and related computer-accessible instructions, e.g.,computer-readable and computer-executable instructions, and data canreside at various times in different storage elements (registers, files,memory addresses, etc.; not shown) in memory 416.

Data storage 420 can comprise a variety of data, metadata, or bothassociated with request of objects (e.g., fragments) in accordance withaspects described herein. Memory 416 also can comprise one or morecomputer-executable instructions for implementation of specificfunctionality of the device 110 in connection with requesting an objectin accordance with aspects described herein. Such computer-executableinstructions can be retained as a memory element labeled requestcomposition instruction(s) 418. In one aspect, as described herein, therequest composition instruction(s) 418 can be stored as animplementation (e.g., a compiled instance) of one or morecomputer-executable instructions that implement and thus provide atleast the functionality of the methods described in the disclosure. Therequest composition instruction(s) 418 also can be transmitted acrosssome form of computer readable media. It should be appreciate thatdifferent request composition instruction(s) can render physically alikedevices into functionally different components, with functionaldifferences dictated by logic (e.g., computer-executable instructionsand data) specific to each one of such network nodes and defined by therequest composition instruction(s) 418.

Memory 416 can be embodied in a variety of computer-readable media.Exemplary computer-readable media can be any available media that isaccessible by a processor in a computing device, such as one processorof the group of one or more processors 408, and comprises, for example,both volatile and non-volatile media, removable and non-removable media.As an example, computer-readable media can comprise “computer storagemedia,” or “computer-readable storage media,” and “communicationsmedia.” Such storage media can be non-transitory storage media.“Computer storage media” comprise volatile and non-volatile, removableand non-removable media implemented in any methods or technology forstorage of information such as computer readable instructions, datastructures, program modules, or other data. Exemplary computer storagemedia comprises, but is not limited to, RAM, ROM, EEPROM, flash memoryor other memory technology, CD-ROM, DVD or other optical storage,magnetic cassettes, magnetic tape, magnetic disk storage or othermagnetic storage devices, or any other medium which can be utilized tostore the desired information and which can be accessed by a computer ora processor therein or functionally coupled thereto.

Memory 416 can comprise computer-readable non-transitory storage mediain the form of volatile memory, such as RAM, EEPROM, and the like, ornon-volatile memory such as ROM. In one aspect, memory 416 can bepartitioned into a system memory (not shown) that can contain dataand/or programming modules that enable essential operation and controlof the device 110. Such program modules can be implemented (e.g.,compiled and stored) in memory element 418, referred to as OSinstruction(s) 422, whereas such data can be system data that isretained in memory element 424, referred to as system data storage 424.The OS instruction(s) 422 and system data storage 424 can be immediatelyaccessible to and/or are presently operated on by at least one processorof the group of one or more processors 408. The OS instruction(s) 422can embody an operating system for the device 110. Specificimplementation of such OS can depend in part on architectural complexityof the device 110. Higher complexity affords higher-level OSs. Exampleoperating systems can include Unix, Linux, iOS, Windows operatingsystem, and substantially any operating system for a computing device.

Memory 416 can comprise other removable/non-removable,volatile/non-volatile computer-readable non-transitory storage media. Asan example, memory 416 can include a mass storage unit (not shown) whichcan provide non-volatile storage of computer code, computer readableinstructions, data structures, program modules, and other data for thedevice 110. A specific implementation of such mass storage unit (notshown) can depend on desired form factor of and space available fordeployment of the device 110. For suitable form factors and sizes of themonitoring device, the mass storage unit (not shown) can be a hard disk,a removable magnetic disk, a removable optical disk, magnetic cassettesor other magnetic storage devices, flash memory cards, CD-ROM, digitalversatile disks (DVD) or other optical storage, random access memories(RAM), read only memories (ROM), electrically erasable programmableread-only memory (EEPROM), or the like.

Features of validation of a request for an asset (e.g., a data object)based on information in the request in accordance with aspects describedherein can be performed, at least in part, in response to execution ofsoftware components (e.g., one or more implementations of requestcomposition instruction(s) 418) by a processor. In particular, yet notexclusively, to provide the specific functionality of device 110, aprocessor of the group of one or more processors 408 in device 110 canexecute at least a portion of the request composition instruction(s)418.

In general, a processor of the group of one or more processors 408 canrefer to any computing processing unit or processing device comprising asingle-core processor, a single-core processor with software multithreadexecution capability, multi-core processors, multi-core processors withsoftware multithread execution capability, multi-core processors withhardware multithread technology, parallel platforms, and parallelplatforms with distributed shared memory (e.g., a cache). In addition orin the alternative, a processor of the group of one or more processors408 can refer to an integrated circuit with dedicated functionality,such as an ASIC, a DSP, a FPGA, a CPLD, a discrete gate or transistorlogic, discrete hardware components, or any combination thereof designedto perform the functions described herein. In one aspect, processorsreferred to herein can exploit nano-scale architectures such as,molecular and quantum-dot based transistors, switches and gates, inorder to optimize space usage (e.g., improve form factor) or enhanceperformance of the computing devices that can implement the variousaspects of the disclosure. In another aspect, the one or more processors308 can be implemented as a combination of computing processing units.

The one or more input/output (I/O) interfaces 404 can functionallycouple (e.g., communicatively couple) device 110 to another functionalelement (component, unit, server, gateway node, repository, etc.) ofnetwork 120, for example. Functionality of the device 110 that isassociated with data I/O or signaling I/O can be accomplished inresponse to execution, by a processor of the group of one or moreprocessors 408, of at least one I/O interface retained in memory element428. Such memory element being represented by the block I/O interface(s)428. In some embodiments, the at least one I/O interface embodies an APIthat permit exchange of data or signaling, or both, via an I/O interfaceof I/O interface(s) 404. In certain embodiments, the one or more I/Ointerfaces 404 can include at least one port that can permit connectionof the device 110 to other functional element of the exemplary networkenvironment 100. In one or more scenarios, the at least one port caninclude one or more of a parallel port (e.g., GPIB, IEEE-1284), a serialport (e.g., RS-232, universal serial bus (USB), FireWire or IEEE-1394),an Ethernet port, a V.35 port, or the like. The at least one I/Ointerface of the one or more I/O interfaces 404 can enable delivery ofoutput (e.g., output data, output signaling) to such functional element.Such output can represent an outcome or a specific action of one or moreactions described herein, such as action(s) in exemplary methods of FIG.5 and/or FIG. 6 .

Bus 412 represents one or more of several types of bus structures,including a memory bus or memory controller, a peripheral bus, anaccelerated graphics port, and a processor or local bus using any of avariety of bus architectures. As an example, such architectures cancomprise an ISA bus, an MCA bus, an EISA bus, a VESA local bus, an AGPbus, and a PCI, a PCI-Express bus, a PCMCIA bus, a USB bus, or the like.

In view of the various aspects of processing a request for an asset in anetwork, such as those described herein, exemplary methods that can beimplemented in accordance with the disclosure can be better appreciatedwith reference to the flowcharts in FIGS. 5-6 . For simplicity ofexplanation, the exemplary methods disclosed herein are presented anddescribed as a series of actions (also referred to as steps),pictorially represented with a block or as a delivered or receivedmessage in a call flow. However, it is to be understood and appreciatedthat implementation, and related advantages, of such methods is notlimited by the order of actions, as some actions may occur in differentorders and/or concurrently with other actions from that shown anddescribed herein. For example, the various methods (also referred to asprocesses) of the subject disclosure can alternatively be represented asa series of interrelated states or events, such as in a state diagram.Moreover, when disparate functional elements (network nodes, units,etc.) implement disparate portions of the methods of the subjectdisclosure, an interaction diagram or a call flow can represent suchmethods or processes. Furthermore, not all illustrated actions ormessages may be required to implement a method in accordance with thesubject disclosure. Further yet, in the illustrated call flows, messagesrelated to routing the emergency communication are represented with anopen-head arrow to pictorially indicate that one or more networkcomponents in addition to those illustrated as receiving a message canenable delivery and related reception of the message within the callflow.

The methods disclosed throughout the subject specification can be storedon an article of manufacture, or computer-readable storage medium, tofacilitate transporting and transferring such methods to computingdevices (e.g., desktop computers, mobile computers, mobile telephones,and the like) for execution, and thus implementation, by a processor orfor storage in a memory.

FIG. 5 is a flowchart of exemplary method 500 for processing a requestfor an asset according to one or more aspects of the disclosure. Theexemplary method 500 can be implemented (e.g., performed or executed) bya computing device, such as an edge cache node (e.g., a node of the oneor more edge cache nodes 130) or a processor of the edge cache node orfunctionally coupled thereto. In certain embodiments, the edge cachenode can implement one or more blocks of the exemplary method 500 inaddition to implementing other logic such as validating a deliveryservice (DS) associated with the edge cache node.

At block 510, a request for a data object is received. The request cancomprise a first identifier indicative of a first value and a secondidentifier indicative of a second value. In one aspect, as describedherein, the first value can be a key identifier (key ID) of a key valuein a mapping relating at least one key ID to at least one key value. Thesecond value can be a predetermined hash value related to the key value.In another aspect, also as described herein, the data object can beassociated with a media asset (e.g., linear-programming asset or anon-linear asset, such as media-on-demand). The request (e.g., objectrequest 116) can be formatted in accordance with various packet-switchedcommunication protocols, such as HTTP, SOAP, SNMP, or the like.Receiving the request can comprise receiving information (e.g., a URLname) indicative of the data object, wherein the information can beformatted according to a specific communication protocol.

At block 520, it is determined (e.g., by the device that implements thesubject exemplary method) if the request is legitimate based at least onthe second value. Block 520 can be referred to as a determining actionwhich, in one embodiment, can comprise determining a hash value byevaluating a hash function (e.g., the MD5 message-digest algorithm) ofthe data indicative of at least a portion of the information (e.g., theURL name) in response to the key value being valid. In addition, thedetermining action can comprise comparing the hash value, which can be asigned hash value, as described herein, to the second value. In responseto the hash value being equal to the second value, the request can bedeemed to be valid. In another embodiment, the determining action cancomprise validating the first value, and determining a third value, suchas a checksum value, by evaluating a function of data indicative of atleast a portion of the information (e.g., the URL name) in response tothe first value being valid. It should be appreciated that the functioncan be a hash function. In such embodiment, the determining action cancomprise comparing the third value, which can be a signed checksumvalue, as described herein, to the second value. In response to thethird value being equal to the second value, the request can be deemedto be valid. In one aspect, validating the first value can comprisevalidating a key value in a mapping relating at least one key identifierto at least one key value.

In response to the request being determined to be legitimate, therequest is transmitted to a network node at block 530. The network edgenode that can implement the exemplary method 500 can be deemed to be afirst network node, thus the network node of block 520 can be deemed tobe a second network node (e.g., origin node 150). In response to thetransmitting action (represented by block 530), the data object isreceived from the network node at block 540. Block 540 can be referredto as the receiving action which, in one embodiment, can comprisereceiving information indicative of the data object. The information canbe formatted according to a specific packet-switched communicationprotocol. In an alternative scenario, in response to the request beingdetermined to be non-legitimate, an error notification (e.g., an HTTP404 status code) can be transmitted to another network node, which canbe referred to as a third network node. As described herein, the thirdnetwork node can be device 110. In the alternative, in response to therequest being non-legitimate, exception handling can be implemented atblock 550. For instance, in one aspect, an error notification (e.g., anexception) can be transmitted to another network node—transmission ofthe error notification can be or can comprise the exception handling.

FIG. 6 is a flowchart of an exemplary method 600 for submitting arequest for an asset according to one or more aspects of the disclosure.The exemplary method 600 can be implemented (e.g., performed orexecuted) by a computing device, such as device 110, configured tocommunicate or in communication with a network repository (e.g., CDN140). In addition or in the alternative, a processor of the computingdevice or functionally coupled thereto can implement (e.g., perform orexecute) the exemplary method 600. At block 610, a request for a dataobject is generated, the request can comprise an identifier indicativeof a first value and a second value. In one aspect, the first valueand/or the second value can be represented as one or more of a numericstring (e.g., a binary number, a decimal number, a hexadecimal number,or the like), an alphabetic string, an alphanumeric string, or the like.

At block 620, the request for the data object can be transmitted to afirst node (e.g., an edge node cache node). The data object can be orcan comprise a media content fragment. In one aspect, the first networknode can be configured to validate the request and to transmit therequest to a second network node in response to the request being valid.In another aspect, generating the request for the data object cancomprise formatting the request according to a specific communicationprotocol. The specific communication protocol can be a web-basedcommunication protocol comprising one or more of HTTP, SOAP, or SNMP.

Various advantages related to validation of a request for an asset(e.g., a data object) based on information in the request in a networkrepository (e.g., a CDN, such as CDN 140) emerge from the foregoingdescription. For example, sparsity of the name space of fragmentsassociated with media assets is accounted for by integrating informationinto the queries, the information permitting validation of a query priorto consuming processing resources of an originating node. It should beappreciated that such integration can be accomplished withoutsubstantive processing overhead, in view that a network edge node thatprocesses such queries typically has available processing resourcessince the node, being a cache node, can be primarily bound by read/writeoperations. For another example, mitigation or avoidance of processingof non-legitimate queries for fragments can readily protect originnode(s) from denial-of-service attacks.

One or more embodiments of the subject disclosure can employ artificialintelligence (AI) techniques such as machine learning and iterativelearning. Examples of such techniques include, but are not limited to,expert systems, case based reasoning, Bayesian networks, behavior basedAI, neural networks, fuzzy systems, evolutionary computation (e.g.genetic algorithms), swarm intelligence (e.g. ant algorithms), andhybrid intelligent systems (e.g. expert inference rules generatedthrough a neural network or production rules from statistical learning).

While the systems, apparatuses, and methods have been described inconnection with exemplary embodiments and specific examples, it is notintended that the scope be limited to the particular embodiments setforth, as the embodiments herein are intended in all respects to beillustrative rather than restrictive.

Unless otherwise expressly stated, it is in no way intended that anyprotocol, procedure, process, or method set forth herein be construed asrequiring that its acts or steps be performed in a specific order.Accordingly, in the subject specification, where a description of aprotocol, procedure, process, or method does not actually recite anorder to be followed by its acts or steps or it is not otherwisespecifically stated in the claims or descriptions that the steps are tobe limited to a specific order, it is no way intended that an order beinferred, in any respect. This holds for any possible non-express basisfor interpretation, including: matters of logic with respect toarrangement of steps or operational flow; plain meaning derived fromgrammatical organization or punctuation; the number or type ofembodiments described in the specification or annexed drawings, or thelike.

It will be apparent that various modifications and variations can bemade without departing from the scope or spirit of the subjectdisclosure. Other embodiments will be apparent from consideration of thespecification and practice disclosed herein. It is intended that thespecification and examples be considered as non-limiting illustrationsonly, with a true scope and spirit of the subject disclosure beingindicated by the following claims.

The invention claimed is:
 1. A system comprising: a user deviceconfigured to: send a request for a content fragment, wherein therequest comprises a Uniform Resource Locator (URL) comprising a firstportion comprising a first identifier identifying a key value and asecond portion comprising a second identifier comprising a referencehash value; and a first network node configured to: receive the requestfor the content fragment; determine, based on the first portion, thatthe key value maps to the first identifier; based on the key valuemapping to the first identifier, determine, using the first identifier,that the key value is valid; based on the key value being valid, hashthe first portion of the URL using the key value; determine, based on avalue of hashing the first portion of the URL matching the referencehash value, that the request is legitimate; and send, based on therequest being legitimate, the request to a second network node.
 2. Thesystem of claim 1, wherein the first network node is further configuredto: receive the content fragment from the second network node inresponse to sending the request to the second network node.
 3. Thesystem of claim 1, wherein the first network node is further configuredto: send an error notification to a third network node in response tothe request being determined to be non-legitimate.
 4. The system ofclaim 1, wherein the first network node is further configured todetermine that the request is legitimate based on the value of hashingthe first portion of the URL matching the reference hash value by:validating the first identifier; determining, based on the firstidentifier being valid, a value signed by the key value by evaluating afunction of data indicative of the first portion of the URL; anddetermining that the request is legitimate based on the value beingequal to the reference hash value.
 5. The system of claim 1, wherein thefirst network node is further configured to validate the firstidentifier by: determining that the first identifier is present in amapping relating at least one key identifier to at least one key value.6. The system of claim 1, wherein the first identifier is included in amanifest associated with the content fragment.
 7. The system of claim 1,wherein the request is encoded according to a web-based communicationprotocol comprising at least one of: a hypertext transfer protocol(HTTP), a simple object access protocol (SOAP), or a simple networkmanagement protocol (SNMP).
 8. One or more non-transitorycomputer-readable media storing processor-executable instructions that,when executed by at least one processor, cause the at least oneprocessor to: receive a request for a content fragment, wherein therequest comprises a Uniform Resource Locator (URL) comprising a firstportion comprising a first identifier identifying a key value and asecond portion comprising a second identifier comprising a referencehash value; determine, based on the first portion, that the key valuemaps to the first identifier; based on the key value mapping to thefirst identifier, determine, using the first identifier, that the keyvalue is valid; based on the key value being valid, hash the firstportion of the URL using the key value; determine, based on a value ofhashing the first portion of the URL matching the reference hash value,that the request is legitimate; and send, based on the request beinglegitimate, the request to a network node.
 9. The one or morenon-transitory computer-readable media of claim 8, wherein theprocessor-executable instructions that, when executed by the at leastone processor, further cause the at least one processor to: receive thecontent fragment from the network node in response to sending therequest to the network node.
 10. The one or more non-transitorycomputer-readable media of claim 8, wherein the processor-executableinstructions that, when executed by the at least one processor, furthercause the at least one processor to: send an error notification to asecond network node in response to the request being determined to benon-legitimate.
 11. The one or more non-transitory computer-readablemedia of claim 8, wherein the processor-executable instructions that,when executed by the at least one processor, cause the at least oneprocessor to determine that the request is legitimate based on the valueof hashing the first portion of the URL matching the reference hashvalue, further cause the at least one processor to: validate the firstidentifier; determine, based on the first identifier being valid, avalue signed by the key value by evaluating a function of dataindicative of the first portion of the URL; and determine that therequest is legitimate based on the value being equal to the referencehash value.
 12. The one or more non-transitory computer-readable mediaof claim 8, wherein the processor-executable instructions that, whenexecuted by the at least one processor, cause the at least one processorto validate the first identifier, further cause the at least oneprocessor to: determine that the first identifier is present in amapping relating at least one key identifier to at least one key value.13. The one or more non-transitory computer-readable media of claim 8,wherein the first identifier is included in a manifest associated withthe content fragment.
 14. The one or more non-transitorycomputer-readable media of claim 8, wherein the request is encodedaccording to a web-based communication protocol comprising at least oneof: a hypertext transfer protocol (HTTP), a simple object accessprotocol (SOAP), or a simple network management protocol (SNMP).
 15. Asystem comprising: a user device configured to: generate a request for acontent fragment, wherein the request comprises a Uniform ResourceLocator (URL) comprising a first portion comprising a first valueidentifying a key value and a second portion comprising a second valuecomprising a predetermined hash value; determine, based on the firstportion, that the key value maps to the first value; based on the keyvalue mapping to the first value, determine, using the first value, thatthe key value is valid; based on the key value being valid, hash thefirst portion of the URL using the key value; and send, based on therequest being valid, the request for the content fragment to a firstnetwork node; and the first network node configured to: receive therequest for the content fragment, validate the request based on a valueof hashing the first portion of the URL matching the predetermined hashvalue, wherein the second portion of the URL comprises the first valueand the second value, and send the request to a second network node whenthe value of hashing the first portion of the URL matches thepredetermined hash value.
 16. The system of claim 15, wherein the firstvalue is included in a key-ID-key-value mapping relating at least onekey identifier to at least one key value.
 17. The system of claim 15,wherein the user device is further configured to generate the requestfor the content fragment by: formatting the request for the contentfragment according to a specific communication protocol.
 18. The systemof claim 17, wherein the user device is further configured to format therequest for the content fragment according to the specific communicationprotocol by: formatting the request for the content fragment accordingto a web-based communication protocol comprising at least one of: ahypertext transfer protocol (HTTP), a simple object access protocol(SOAP), or a simple network management protocol (SNMP).
 19. The systemof claim 15, wherein the first value is included in a manifestassociated with the content fragment.
 20. One or more non-transitorycomputer-readable media storing processor-executable instructions that,when executed by at least one processor, cause the at least oneprocessor to: generate a request for a content fragment, wherein therequest comprises a Uniform Resource Locator (URL) comprising a firstportion comprising a first value identifying a key value and a secondportion comprising a second value comprising a predetermined hash value;determine, based on the first portion, that the key value maps to thefirst value; based on the key value mapping to the first value,determine, using the first value, that the key value is valid; based onthe key value being valid, hash the first portion of the URL using thekey value; and send, based on the request being valid, the request forthe content fragment to a first network node, wherein the first networknode is configured to validate the request based on a value of hashingthe first portion of the URL matching the predetermined hash value,wherein the second portion of the URL comprises the first value and thesecond value, and wherein the first network node is configured to sendthe request to a second network node when the value of hashing the firstportion of the URL matches the predetermined hash value.
 21. The one ormore non-transitory computer-readable media of claim 20, wherein thefirst value is included in a key-ID-key-value mapping relating at leastone key identifier to at least one key value.
 22. The one or morenon-transitory computer-readable media of claim 20, wherein theprocessor-executable instructions that, when executed by the at leastone processor, cause the at least one processor to generate the requestfor the content fragment, further cause the at least one processor toformat the request for the content fragment according to a specificcommunication protocol.
 23. The one or more non-transitorycomputer-readable media of claim 22, wherein the processor-executableinstructions that, when executed by the at least one processor, causethe at least one processor to format the request for the contentfragment according to the specific communication protocol, further causethe at least one processor to format the request for the contentfragment according to a web-based communication protocol comprising atleast one of: a hypertext transfer protocol (HTTP), a simple objectaccess protocol (SOAP), or a simple network management protocol (SNMP).24. The one or more non-transitory computer-readable media of claim 20,wherein the first value is included in a manifest associated with thecontent fragment.